Address for correspondence: Prof. Henryk Witmanowski MD, PhD, Department of Plastic, Reconstructive and Aesthetic Surgery, Medical College, Nicolaus Copernicus University, 9-11 M. Skłodowska-Curie St, 85-094 Bydgoszcz, phone: +48 52 585 4017, e- mail: hewit7@wp.pl Received: 21.06.2016, accepted: 2.08.2016.
Basal cell nevus syndrome (Gorlin-Goltz syndrome):
genetic predisposition, clinical picture and treatment
Henryk Witmanowski1,2, Paweł Szychta1,3, Katarzyna Błochowiak4, Arkadiusz Jundziłł3, Rafał Czajkowski5
1 Department of Plastic, Reconstructive and Aesthetic Surgery, Medical College in Bydgoszcz, Nicolaus Copernicus University in Torun, Poland
2Department of Physiology, Poznan University of Medical Sciences, Poznan, Poland
3 Department of Surgical Oncology and Breast Diseases, Institute of Polish Mother’s, Memorial Hospital Research Institute, Lodz, Poland
4Department of the Oral Surgery, Poznan University of Medical Sciences, Poznan, Poland
5 Department of Dermatology, Sexually Transmitted Diseases and Immunodermatology, Medical College in Bydgoszcz, Nicolaus Copernicus University in Torun, Poland
Adv Dermatol Allergol 2017; XXXIV (4): 381–387 DOI: https://doi.org/10.5114/ada.2017.69323
Gorlin-Goltz syndrome (Online Mendelian Inheritance in Man, MIM, 109400), also called nevoid basal cell car- cinoma syndrome (BCCS) or basal cell nevus syndrome (BCNS), is a multisystemic autosomal dominant disorder with a high penetrance and variable expressiveness [1].
The classical triad is composed of multiple basal cell car- cinomas, keratocystic odontogenic tumors and bifid ribs.
The disease is variably associated with other neurologi- cal, ophthalmic, endocrine and genital manifestations, with onset during the first, second and third decades of life [2]. The estimated prevalence is 1/60,000 and varies from 1/30 827 to 1/256 000 [3, 4]. It affects males and females equally and arises in all ethnic groups, but most of reported cases are in whites [5].
The genodermatosis is caused in most cases by het- erozygous mutations in tumor suppressor gene PTCH, located on chromosome 9q22.3 [6]. Molecular germline mutations in BCNS include frameshift, nonsense, mis- sense and splicing mutations, exonic, multi-exonic or rearrangements [7]. The PTCH1 gene encodes a trans- membrane glycoprotein that acts as the antagonist re- ceptor for the sonic hedgehog ligand in the hedgehog and smoothened (SMO) signaling pathways [8]. Hedge- hog and SMO signaling pathways regulate cell growth and development and thus their disruption results in developmental anomalies and tumors [9]. Up to 60% of patients can suffer from BCNS resulting from de novo mutations [10].
In overall, the disorder comprises five prevalent clini- cal manifestations: multiple nevoid BCCS, keratocystic odontogenic tumors (KOT), skeletal anomalies, lamellar
calcification of falx cerebri and palms and/or plantar pits [11]. A detailed list of diverse clinical features in BCNS is displayed in Table 1 and comprises developmental anom- alies together with tumors.
Developmental defects in BCNS include craniofacial anomaly, together with anomalies of the neurological system, axial skeleton, hands and feet. A characteristic coarse facial appearance includes frontal and temporal bossing, high and broad forehead, well-developed supra- orbital ridges, hypertelorism, broad nasal root and wide nasal bridge, mandibular prognathism, internal strabis- mus and rotatory nystagmus [12, 13]. The symptoms can be associated with hypoplastic maxilla and crossbite teeth relationship, high arched palate, cleft lip and pal- ate, malocclusion and impacted teeth [12]. Macrocephaly is present at birth and is often associated with cerebral ventricular dilatation and empty sella [7]. Lamellar falx calcification is the most consistent radiological feature, which is usually present by the second decade and is asymptomatic [14]. Thoracic cage anomalies are con- genital dysmorphic features present in the unchanged state from the fetal period in the form of bifid, splayed, or fused ribs, which are found incidentally on chest X-ray [11]. Anomalies of axial skeleton comprise spina bifida oc- culta, kyphoscoliosis, fusion defects and hemi vertebrae [12]. Palmar and/or plantar pits are superficial point de- pressions on palms and soles asymmetrically prevalent in BCNS in the late second decade. They are caused by a partial or complete absence of the horny layer in sharp- ly defined areas ranging from 2 to 3 mm in diameter and 1 to 3 mm in depth [2].
Tumors related to BCNS are BCC, KOT, epidermoid cysts of skin, ovarian fibroma, medulloblastoma, lympho- mesenteric cysts, and cardiac fibroma in the descending frequency [15]. Nevoid BCCs are multiple and polymor- phic. Naevus emphasizes their early onset with BCCs developed in about 50% of patients aged > 20 years and in up to 90% of patients by the age of 40 [16, 17]. Their
appearance and clinical characteristics are variable, from less aggressive brownish flesh-colored basal cell nevi to very aggressive forms present usually in sun-exposed areas [18]. Jaw cysts, KOTs, are benign cystic lesions con- taining a clear fluid with a slowly progressive nature, local invasion tendency affecting the teeth, and a high recurrence rate of 60% due to thin lining of the fibrous Table 1. Clinical picture of patients with BCNS
Summarized clinical manifestations
Detailed clinical manifestations Reference Our patient
[17] [29] [30]
Tumors BCC 75 90 37.8 +
KOT 75 90 86.3 +
Epidermoid cysts of the skin NA > 50 NA +
Ovarian fibroma NA 24 12.5
Medulloblastoma NA 5 3.3
Lymphomesenteric cysts NA < 5 NA
Cardiac fibroma NA 2.5 2.1
Head Calcified falx cerebri 92 > 85 79.4 +
Coarse face NA 70 27.9 +
Macrocephaly 80 50 26.5 +
Prognathism 33 NA 25.2
Hypertelorism 6 NA 68.8
Highly arched eyebrows NA NA 44 +
Frontoparietal bossing 66 NA 47
Broad nasal bridge 59 NA 58.4 +
Eyeball abnormalities NA 7 NA
Cleft lip/palate 4 6 9
Neurological system Hydrocephalus NA NA 16.2 +
Bridging of sella turcica 26 NA 23.7
Mental retardation NA NA 17.6
Epilepsy NA NA 9
Axial skeleton Vertebral anomalies 35 60 15.1 +
Kyphoscoliosis NA 30–40 NA
Rib anomalies 45 60 36.4 +
Sprengel deformity 4 NA 2.7
Pectus deformity 23 NA 6.1
Hands/feet Palmar and/or plantar pits 80 65 69.2 +
Syndactyly NA NA 2.1
Polydactyly NA < 5 1.5
Short 4th metacarpals 29 NA 10.5 +
Flame shaped lucencies of hands/feet NA NA 2.5
Family history NA NA 48.4
NA – not applicable.
capsule and presence of satellite cysts [12]. The tumors, present in 75% of patients with BCNS, are found as the first features of the syndrome either incidentally on ra- diographic examination of jaws often as bilateral lesions or treated due to a secondary infection or displacement of developing teeth [19, 20]. The other tumors occurring with a low prevalence in BCNS are medulloblastoma, car- diac fibroma and ovarian fibroma [7]. The age predilec- tion for tumors in BCNS is in the first to third decade of life, with the onset age of cardiac fibroma at 0–1 months, medulloblastoma at 2–3 years, BCC at 3–53 years, KOT at 6–12 years and ovarian fibroma at 16–45 years [12].
Clinical and radiological diagnostic criteria were proposed by Evans et al. and modified by Kimonis et al.
(Table 2) [15, 16]. The BCNS is diagnosed based on meet- ing either two major criteria, or one major criterion and two minor ones [4].
The aim of our work is to present a case of Gor- lin-Goltz syndrome, review its genetic predisposition, clinical picture and treatment.
A 39-year-old male patient from the Central-Eastern Europe was referred to the Plastic Surgery Clinic with multiple BCCs (Figure 1). On general physical examina- tion, the patient was well built and nourished. His coarse facial appearance comprised macrocephaly, highly arched eyebrows and a broad nasal bridge (Table 1).
The first BCC appeared when he was 17 years old and appeared gradually on various parts of his body, starting gradually from the abdominal wall, posterior trunk and face. He was not exposed to excessive environmental risk factors for skin cancer. In the past, the BCC lesions were treated with various modalities over years, including la- ser therapy, radiotherapy and surgery, and were biopsy proven. In our clinic, diagnosis of BCC was confirmed by histopathology following the surgical excision (Figure 2).
The patient was evaluated systemically for other anomalies of the skeletal, cardiovascular, central ner- vous and integumentary systems. He presented with abnormal dentition associated with unerupted teeth. In the past, he was surgically treated for KOT, which was
histologically proven (Figure 2). Computed tomography scan of the head revealed lamellar calcification of the falx cerebri (Figure 3 B). He was diagnosed for hydrocepha- lus with skull X-ray when he was aged 2 years. Electro- encephalogram, ECG, ECHO and abdominal US studies were within their normal limits. The patient had a biopsy- proven epidermoid cyst in his left lumbar region. There were multiple brownish palmar pits on both his hands (Figure 4). The patient’s other medical and family history was noncontributory. The patient was single and did not have any children.
The clinical, radiological and histopathological find- ings met major and minor criteria for diagnosis of the BCNS (Gorlin-Goltz syndrome) (Table 2).
The diagnostic process in patients suspected of BCNS includes physical examination and imaging studies. The physical examination must include oral exploration, ce- phalic diameter, craniofacial morphology, skin explora- tion, and evaluation of the palms and soles [4]. Skull X-rays, orthopantogram, chest X-ray, and spinal X-ray are required as complementary tests. Ultrasound examina- tions are used to diagnose cardiac and ovarian fibromas [1]. Brain magnetic resonance imaging may prove to be important for the detection of meningiomas or medul- loblastomas in patients with BCNS in the first years of life [4]. The diagnosis of BCNS can be confirmed by the detection of a mutation of the PTCH gene although PTCH mutations have also been found in other sporadic malig- nancies, such as medulloblastomas, skin trichoepithelio- mas, esophageal squamous cell carcinomas, squamous cell carcinomas, breast cancer, colon cancer, as well as in KOT [21].
The therapy of patients with BCNS requires a mul- tidisciplinary approach. For the limited BCCs, various forms of treatment have been described, and the first- line treatment is usually surgical excision by standard or micro excisional/Mohs techniques, especially for nodular or aggressive BCCs.
Minimally invasive treatment modalities for low risk superficial BCCs include electrodessication and curet- Table 2. Diagnostic criteria for BCNS in our patient (based on Kimonis et al. [15])
Major criteria Our patient Minor criteria Our patient
Multiple (> 2) BCCs or 1 BCC in
a patient aged < 20 years + Macrocephaly determined after adjustment for height: OFC
(occipitofrontal circumference) > 97th percentile + Mandibular or maxillary KOT
confirmed on histology + Congenital malformations: cleft lip/palate, frontal bossing,
coarse face, moderate or severe hypertelorism + Pitted depressions on hands or feet
(palmar or plantar pits) (≥ 3 lesions) + Skeletal abnormalities: Sprengel deformity, pectus deformity,
finger syndactyly +
Ectopic calcification: lamellar
calcification of the falx cerebri +
Radiological abnormalities: bridging of the sella turcica, vertebral anomalies (hemivertebrae, fusion or elongation of
the vertebral bodies), deformities of hands and feet
+
Bifid, fused or markedly expanded ribs + Ovarian fibroma
First-degree relative with BCNS Medulloblastoma
Figure 1. Photograph of the patient showing multiple BCCs of the face and trunk
A
C
E
B
D
F
tage, cryotherapy, carbon dioxide laser ablation, photo- dynamic therapy (PDT) or electrochemotherapy. Photo- dynamic therapy is considered as an effective and safe therapy for superficial BCCs and in nodular BCCs < 2 mm in thickness, by use of a photosensitizing dye given in- travenously or topically [3]. However, the procedure is painful and can induce erythema, scabbing and blister
formation. Pharmacological topical approaches to treat superficial BCCs comprise creams with 0.1% tretinoin, 5% fluorouracil or 5% imiquimod [22]. Topical approaches require a long duration which may lead to poor patient compliance. Immunomodulators, such as imiquimod, can lead to local inflammation and need to be applied on a limited area of the affected skin [23]. Systemic Figure 3. Radiological findings associated with Gorlin syn-
drome: A – orthopantogram showing multiple jaw cysts (unilocular well-defined radiolucent lesions with sclerotic borders) in relation to impacted and unerupted teeth – odontogenic keratocysts, B – CT scan of the head showing calcification of the falx cerebri
A B
Figure 2. Histological sections of 4 BCCs: A – 10× magnification, B – high mitotic activity at 40× magnification, C – pali- sades on the periphery and the figures of cell division at 40× magnification, D – focal acanthosis at 10× magnification
A
C
B
D
treatment includes oral retinoids (isotretinoin at doses of 0.5–1 mg/kg/day) or oral etretinate (0.5–1 mg/kg/day) in lesions of less than 1 cm as well as capecitabine (a sys- temic prodrug of fluorouracil) as palliative treatment [24, 25]. Oral retinoids inhibit the development of new BCCs [24]. On contrary, radiation therapy can have possible del- eterious effects on the local skin cancer recurrence risk or new tumor growth [13].
KOT is treated with surgical excision in the form of enucleation, curettage, marginal osteotomy, or segmen- tal osteotomy [12]. Alternative approaches are cryother- apy or application of Carnoy’s solution [26]. Recurrence after surgery is reported at a rate of 6–60% and is attrib- utable to incomplete resection, dental lamina remaining within the maxillas, or the presence of satellite cysts [4].
Therefore, close dental follow-up is obligatory [2].
Future treatment options in BCNS patients include PTCH1- or SMO-specific targeted drugs which prevent the expression of tumor mediating genes within the hedge- hog pathway. Vismodegib and sonidegib are hedgehog pathway inhibitors approved for metastatic or recurrent BCC or patients who are not surgical or radiation candi- dates [10]. Vismodegib actually reduces the BCC tumor burden and blocks growth of new BCC in patients with Gorlin syndrome [27]. The future treatment alternatives are modulating therapies of hedgehog signaling, which include Gli1 inhibitor, PI3K-mTOR inhibitor, and PKC in- hibitor [28].
In summary, numerous symptoms of the BCNS geno- dermatosis can be successfully treated systemically or locally, usually with surgical interventions or other thera- peutic alterations. Patients with BCNS require screening at birth for cardiac, palatal or neural defects, for medul- loblastoma twice yearly in the early childhood, for KOT from late childhood and for BCCs throughout life with at least two dermatological examinations on a yearly basis.
Children should be evaluated for hydrocephalus in case of a rapid increase in the occipitofrontal circumference.
A yearly panoramic X-ray study of jaws for KOT screen-
ing is recommended in children older than 8 years. In turn, radiotherapy and frequent computer tomography are relatively contraindicated. Sun exposure should be limited. Patients with BCNS have a very good prognosis with normal life expectancy, except from rare cases of very aggressive multiple BCCs or medulloblastoma [4].
Patients and their children should be counselled about the hereditary nature of BCNS, and they should be of- fered genetic testing for familiar cancer syndrome [29].
Conflict of interest
The authors declare no conflict of interest.
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